DE4118829C2 - Method for operating a spinning machine and device for carrying out the method - Google Patents

Description

The invention relates to a method according to the Preamble of claim 1 and a method according to the preamble of claim 8.

As a drive for a spinning machine with a variety of Workplaces, for example with a ring spinning machine a large number of spindles, is currently essentially the Tangential belt drive use. The advantage of this type drive type, namely the relatively low cost the disadvantage compared to that due to the different slip between the tangential belt and the drive pulley on the individual Workplaces do not have a completely synchronized spindle run is ensured.

For this reason, single spindle drives have recently become available developed, which are cheap to manufacture and others on the one hand, through a correspondingly high degree of efficiency drive costs of the spinning machine in the required scope hold.

A generic method and a generic one Device goes out of a ring spinning machine DE 38 05 662 A1.

With this prior art, however, is as such common when processing thread-like material (see e.g. DE 35 14 801 A1), none Precaution taken, in the event of a malfunction  Operation shutdown.

The invention is therefore based on the object a method for operating a spinning machine with separate electromotive drives to further develop each job in such a way that also in In the event of a fault, an operational shutdown is possible the effort for this should be kept low.

In addition, the invention has for its object a To create device for performing the method.

The invention solves these problems with the features of claims 1 and 8.

With the invention it is possible that after Detection of a triggering event and thereby caused shutdown of the electric motor of the affected job an electromechanical transducer to activate another mechanical device, e.g. B. a match stop (see. DE 39 10 181 A1) controlled can be without a signal regarding the detect event first to a central controller must be conducted and without any special Power supply of the mechanical to be operated Setup must be made. That is also a significant reduction in cabling  connected and the energy when stopping the Motors is not lost as much, but can used to actuate the mechanical converter will.

Advantageous developments of the invention result from the Subclaims, i.e. claims 2 to 7 and 9 to 15.

It is further stated that the features of claims 2 to 7 by the older patent application P 40 10 376.5, the have been published, are known per se. Corresponding applies to claims 9 to 15.

The invention based on several in the drawing illustrated embodiments explained in more detail. In the Drawing shows

Figs. 1 to 5 each show the schematic block diagram of various embodiments of the invention.

In Fig. 1, an electric motor 1 is shown with the working windings W1, W2, W3, which is preferably designed as a synchronous motor or reluctance motor. This motor 1 is the drive for a job, not shown, of a spinning machine, for example for the spindle of a ring spinning machine. The free ends of the interconnected star - the delta connection is of course also possible - work windings W1, W2 and W3 are means controllable electronic switches S1, S2 and S3 connected to the associated phases r, s, t of a frequency converter 2 . The tax ble electronic switches can be designed as transistors, thyristors or the like and are controlled by a control unit 3 , which in turn also takes over the corresponding control of the frequency converter 2 when starting, in the operating phase and when stopping the electromo tor 1 .

The switches S1, S2 and S3 are designed as two- or three-pole switches. While one pole of the switch is connected to the associated phase r, s, t of the frequency converter 2 , another pole is connected to an input of a rectifier 5 . The rectifier 5 is connected with its DC voltage output to an electromechanical converter 6 , for example an electromagnet. The electromechanical transducer 6 is coupled to the mechanical device to be actuated, for example one associated with the corresponding work station of the spinning machine sliver stop device.

Furthermore, each work station is assigned a sensor for detecting those states of the work station that make it necessary to release the mechanical device 7 . This is necessary in any case in the event of a thread breakage, but can also take place when the spinning machine or the work station is shut down or in another event impairing the proper functioning of the work station.

The sensor signal is fed to an electronic evaluation unit 4 , which is connected to the control unit 3 and detects the triggering event on the basis of the sensor signal supplied to it. In addition, the frequency converter 2 and the control unit 3 can be assigned not only to one, but to several or all work stations of a spinning machine. Furthermore, the operating parameters of a work station can be transmitted by the control unit 3 to a central machine control and can thus be processed further in the sense of a normal operating data acquisition (PDA).

The operation of the embodiment of the invention shown in Fig. 1 is explained below: In the start-up phase, the control unit 3 controls the switches S1, S2, S3 so that the free ends of the working windings W1, W2 and W3 of the electric motor 1 with the associated Phases r, s and t of the frequency converter 2 are connected. After the rated speed has been reached, the switch S3 is activated such that the working winding W3 is separated from the phase t and the voltage U _{i present} across the windings W2 and W3 is supplied to the electronic evaluation unit 4 . This means that the winding W3 no longer serves as a working winding, but is used as a sensor winding in the operating phase of the motor, as described in German patent application P 40 10 376.5. The sum voltage U _i , which results from the superimposition of the voltage induced in the winding W3 and from the voltage across the winding W2, thus represents the sensor signal that is analyzed by the electronic evaluation unit 4 .

If the torque to be output by the motor 1 changes (load change), as is the case, for example, when a thread break occurs, the magnet wheel angle of the synchronous or reluctance motor changes. This also results in a change in the phase position of the voltage induced in the winding W3, which can also be determined by the electronic evaluation unit 4 on the basis of the total voltage U _i supplied to it. If the phase change is greater than a predetermined value, the electronic evaluation unit 4 assumes that there is a thread break and emits a corresponding signal to the control unit 3 .

In addition to evaluating a pure phase change, however, it is also possible to evaluate the absolute phase difference between one of the phase voltages and that in the working windings W3 of the electric motor 1 serving as a sensor winding. In addition, the frequency of the sensor signal U _i can also be evaluated, so that a possible falling out of the synchronous motor is also detected.

After detection of the triggering event by the electronic evaluation unit 4 and the output of a corre sponding signal to the control unit 3 , the controllable electronic switches S1, S2 and S3 are controlled so that the motor 1 is separated in three phases from the frequency converter 2 and the free ends of all work windings W1, W2 and W3 are connected to the inputs of the rectifier 5 . Thus, while the electric motor 1 is brought to a standstill in this way, it is switched to the generator mode and the electromechanical converter 6 is supplied with the electrical energy which is thereby released. By actuating the electromechanical transducer 6 , the mechanical device to be actuated, for example the match stop device, is activated on the one hand and, on the other hand, a sufficient braking torque for its sufficiently rapid shutdown is generated by the load on the electric motor 1 operating in generator mode.

After the electromechanical transducer 6 is supplied with electrical energy only during the shutdown phase of the electric motor 1 , the mechanical device 7 to be actuated must be designed such that it remains automatically in the fourth state after being activated once by the electromechanical transducer. This can be achieved, for example, by designing the mechanical device 7 as a spring-loaded system which is unlocked by the actuation by means of the electromechanical transducer 6 . After eliminating the state of the spinning machine, on the basis of which the mechanical device 7 has been activated, it can be reset to the activatable state either manually or by an automatic mechanical device which replaces the operator (for example an automatic thread attachment device patrolling the machine) .

While in the circuit variant shown in FIG. 1 the mechanical device 7 is forcibly activated when the motor 1 is stopped by the corresponding activation of the controllable electronic switches S1, S2 and S3, the motor can be stopped (in addition to the stop by corresponding activation of the frequency converter) 2 ) by a slight change in the interconnection so that only the motor 1 is stopped without simultaneous activation of the mechanical device 7 . For this purpose, only the controllable electronic switches S1 and S2 are designed as three-pole switches and the controllable electronic switch S3 as four-pole switches. In this case, the additionally created poles are to be electrically connected to one another, as a result of which the work windings W1, W2 and W3 are short-circuited in the shutdown phase when the switch 3 is actuated accordingly. The motor 1 is stopped by the braking torque generated in this way and the mechanical device 7 remains in its activatable state.

The embodiment of the invention shown in FIG. 2 differs from the first exemplary embodiment described above only in that initially only two controllable electronic switches S2, S3 are arranged in the supply lines of the phases s, t of the electric motor 1 . The electrical signal induced in the operating phase in the working winding W3 serving as a sensor winding is, as described above, supplied as a sensor signal to the electronic evaluation unit 4 and evaluated by it in the same way.

The detection of the triggering event, the control of the controllable electronic switches S2 and S3 and the actuation of the mechanical device 7 by the electrical energy generated during the shutdown phase by the electrical motor 1 is also carried out as described above.

The only difference is that the rectifier 5 is only connected to the ends of the windings W3 and W2 in the shutdown phase and thus rectifies the sum of the voltages induced in these windings. To reduce the circuit complexity, the controllable electronic switch S3 can also be designed as a two-pole switch instead of a three-pole switch. In this case, the corresponding input of the rectifier 5 must be connected to the input of the electronic evaluation unit 4 , which is located on one of the two poles of the controllable electronic switch S3. That is, in the operating phase, the end of the winding W3 is already connected to the corresponding input of the rectifier 5 , so that to stop the electric motor 1 and at the same time activate the mechanical device 7, the controllable electronic switch S2 must be controlled so that it which connects one end of the working winding W2 to the corresponding second input of the rectifier 5 . This circuit simplification is of course also possible in the embodiment of the invention shown in FIG. 1.

In addition, a switch S1 arranged in the third supply line of the electric motor 1 (phase r) is shown in broken lines in FIG . This two-pole scarf ter S1, the second pole of which is also connected to the input of the rectifier 5, which is also connected to a pole of the controllable electronic switch S2, enables the short-circuiting of the working windings W1 and W2 with appropriate control by the control unit 3 in the shutdown phase. If the voltage induced in the working windings W2 and W3 is applied to the input of the rectifier 5 in the shutdown phase by means of the controllable electronic switches S2 and S3, the motor is stopped and the mechanical device 7 is simultaneously activated. If the motor is also separated from the third phase (r) by appropriate control of switch S1 and the winding W1 is short-circuited with winding W2, the voltage additionally induced in winding W1 results in a higher braking torque in the stop set phase.

In addition, the motor 1 can also be stopped by switching the controllable electronic switches S1 and S2 (short-circuit of the windings W1 and W2) with sufficient braking torque, without simultaneous actuation of the mechanical device 7 . However, this requires the design of the switch S3 as a three-pole switch, since the corresponding input of the rectifier 5 must not be connected to the winding W3 in the operating phase. The possibility described above for reducing the circuit complexity is therefore not applicable in this case.

The schematic block diagram of a third embodiment of the invention shown in FIG. 3 is largely identical to the second embodiment described above. Differences exist on the one hand in the design of the controllable electronic switches S2 and S3 as a simple on / off switch or as a two-pole switch with an additional switch-off function (three-pole switch with a pole not connected) and on the other hand that two inputs of the Rectifier 5 are connected via another controllable electronic switch S5 to the ends of two initially arbitrary working windings (in the case shown here with the ends of the windings W2 and W3).

In the operating phase, the controllable electronic scarf ter S2, S3 and S5 are controlled by the control unit 3 so that the switch S2 is in the closed state that the voltage U _i applied across the two working windings W2 and W3 by means of the switch S3 to the electronic evaluation unit 4 is placed and that the switch S5 is in the open state. If the electronic evaluation unit 4 detects an event that makes it necessary to actuate the mechanical device 7 , it sends a corresponding signal to the control unit 3 , which then controls the two switches S2 and S3 into the open (off) state and the switch S5 closes.

As described above, this results in the activation of the mechanical device 7 by means of the electromechanical converter 6 and the stopping of the motor with sufficient braking torque. If the engine is to be stopped, but not the actuation of the mechanical device 7 , the control unit 3 merely controls the two switches S2 and S3 into the open (off) state and keeps the switch S5 in the open state. As a result, the motor is separated from the frequency converter 3 in two phases (phases s and t). Since in this case in the working windings W1, W2 and W3 there is no additional braking torque due to appropriate induction processes, but this is desired, the switches S2 and S3 can be designed as two- or three-pole changeover switches, the additional poles being electrically connected to one another . Thus, the motor 1 can be separated from the two phases s and t for stopping and at the same time the corresponding windings W2 and W3 can be short-circuited. In this case, however, care must be taken that, unlike in FIG. 3, it is not the ends of these two windings that are connected to the inputs of the rectifier 5 , but rather an input of the rectifier 5 with the end of the third winding W1 in electrical fashion Contact is there. Otherwise, despite the closing of the switch 5 during the stopping process, actuation of the mechanical device 7 is not possible.

The embodiment of the invention shown in FIG. 4 differs from the embodiment shown in FIG. 3 only in that the working winding W3 serving as a sensor winding during the operating phase of the motor 1 also has an additional electronic switch that can be controlled by the control unit 3 can be separated from the star point of the windings. Hereby is achieved that is from the electrostatic African evaluation unit 4 to be monitored voltage U _i is equal to the voltage induced in the sensor winding serving as a working winding W3 voltage, which is the electronic evaluation unit 4 now supplied floating.

This makes it easier to detect the triggering event, since the actual sensor signal, ie the voltage induced in the winding W3, is no longer superimposed by the voltage across the winding W2, as in the examples described above. The rest of the operation of this exemplary embodiment is identical to the third exemplary embodiment described above, with the difference that the rectifier 5 either only the voltage induced in the winding W3 (as shown in FIG. 4) or as described in the preceding examples Induced voltage can be supplied in two working windings.

In the last exemplary embodiment shown in FIG. 5, electronic switches S1, S2, S3 which can be controlled by the control unit 3 are arranged in all three supply lines between the motor 1 and the frequency converter 2 . An additional sensor winding W4 is arranged in the motor 1 , which can also be connected in a conventional manner to all three phases r, s, t of the frequency converter 2 during the operating phase. The voltage U _i (sensor signal) induced in the sensor winding W4 is fed to the electronic evaluation unit 4 . The triggering event is detected on the basis of the sensor voltage U _i as described above.

If a triggering event is detected, the control unit 3 controls the controllable electronic switches S1, S2 and S3 in such a way that the motor 1 is separated from at least two phases of the frequency converter 2 . Preferably, as shown in FIG. 5, the windings W1, W2 and W3 of the motor 1 are short-circuited in order to achieve a sufficiently high braking torque. In this shutdown phase, the control unit 3 controls the additionally available controllable electronic switch S5, which is arranged in a connecting line between an input of the rectifier 5 and one end of the sensor winding W4, in the closed state.

In this way, by the existing connection of the other winding end of the winding W4 to the second input of the rectifier 5 , the voltage U _i induced in the winding W4 during the stopping phase is supplied to the rectifier. This ensures that the mechanical device 7 is actuated by means of the electromechanical transducer 6 .

Of course, also in this exemplary embodiment, instead of the voltage induced in the winding W4, the voltage induced in at least one of the windings W1, W2 and W3 can be fed to the rectifier. It is only important to ensure that during the shutdown phase the corresponding windings are not short-circuited by means of the switches S1, S2, S3 arranged in the supply lines of the motor if actuation of the mechanical device 7 is desired.

Claims (15)

1. A method for operating a spinning machine, in particular a ring spinning machine, in which each work station is equipped with a separate electromotive drive (electric motor 1 ), characterized in that a triggering event is detected by means of a sensor and an electronic evaluation unit ( 4 ) connected downstream thereof, and the electromotive Drive (electric motor 1 ) is stopped after detecting the triggering event and that with the electrical energy induced during the shutdown of the electric motor ( 1 ) in at least one winding (W1, W2, W3, W4) present in the electric motor ( 1 ), an electromechanical converter ( 6 ) is supplied, which serves to activate the mechanical device ( 7 ) to be actuated. 2. The method according to claim 1, characterized in that the triggering event is detected by evaluating the in a Elek tromotor ( 1 ) arranged sensor winding (W4) induced voltage (U _i ) ( Fig. 5). 3. The method according to claim 1, characterized in that the triggering event by evaluating the in at least one ner, during the operating phase of the electric motor ( 1 ) from the associated phase (r, s, t) separated working winding (W1, W2, W3) induced voltage ( Fig. 4) is detected. 4. The method according to claim 1, characterized in that the triggering event by evaluating the total voltage from the in a, during the operating phase of the electric motor ( 1 ) separated working winding (W1, W2, W3) induced voltage and from one of the non- disconnected windings applied voltage is detected. 5. The method according to any one of claims 2 to 4, characterized records that the triggering event is a change in the Frequency or the phase position of the voltage to be evaluated is. 6. The method according to one or more of the preceding claims che, characterized in that the in at least one Winding of the electric motor induced voltage in the same direction tet and the DC voltage thus generated for control an electromagnet is used. 7. The method according to one or more of the preceding claims, characterized in that the activated mechanical device ( 7 ) automatically remains in the activated state after the engine is stopped. 8. Device for performing the method according to one of claims 1 to 7, characterized in that
that switching elements (S1, S2, S3) which can be controlled by a control unit ( 3 ) are arranged in at least two feed lines of the electric motor ( 1 ),
that after detecting the triggering event, the control unit ( 3 ) controls the switching elements (S1 to S5) such that the motor is stopped and at least the voltage induced in a winding (W1 to W4) is applied to the input of a rectifier ( 5 ) and
that the rectifier ( 5 ) is followed by an electromechanical converter ( 6 ) which actuates the mechanical device ( 7 ) coupled to it. 9. The device according to claim 8, characterized in that the electric motor ( 1 ) is designed as a three-phase synchronous motor, the windings (W1, W2, W3) are connected in a star connection without a star point conductor or in a delta connection and that in at least two feed lines between the electric motor ( 1 ) and the converter ( 2 ) through the control unit ( 3 ) controllable switching elements (S1, S2, S3) are arranged. 10. The device according to claim 9, characterized in that during the operating phase, a winding (W3) of the electromotor is separated from the associated phase (t) by means of the switching element (S3) and serves as a sensor winding that the electronic evaluation unit ( 4 ) voltage induced in a working winding (W3) separated from the feeding phase or the sum of the voltage induced in the working winding (W3) separated from the feeding phase and the voltage present across one of the two non-separated windings (W2) is supplied and that the evaluation unit ( 4 ) detects a thread break as a triggering event from the change in the phase position of the voltage (ie the magnet wheel angle) caused by a load change and outputs a signal to the control unit ( 3 ) ( Fig. 1, 2, 3 and 4). 11. The device according to claim 9 or 10, characterized in that in all three feed lines controllable Schaltelemen te (S1, S2, S3) are arranged and that after detection of the triggering event, the switching elements (S1, S2, S3) such from the control unit ( 3 ) are controlled so that all three feed lines of the motor are separated from the voltage source ( 2 ) and connected to the inputs of the rectifier ( 5 ) ( FIG. 1). 12. The apparatus of claim 9 or 10, characterized in that after detection of the triggering event, the switching elements (S1, S2, S3) are controlled by the control unit ( 3 ) in such a way that two feed lines of the electric motor ( 1 ) from the converter ( 2 ) separately and to the inputs of the rectifier ( 5 ) and that optionally the third feed line is also separated from the converter ( 2 ) and short-circuited with one of the other two feed lines ( Fig. 2). 13. The apparatus of claim 9 or 10, characterized in that two terminals of the electric motor ( 1 ) are connected to the inputs of the rectifier ( 5 ) and that in one of the connecting lines, a switch element (S5) controllable by the control unit ( 3 ) is arranged is, after detection of the triggering event at least two feed lines separated from the converter ( 2 ) and the switching element (S5) is controlled in the closed state ( Fig. 3). 14. The apparatus according to claim 9, characterized in that a further controllable by the control unit switching element (S4) is present, which together with the switching element (S3) during the operating phase one of the windings (W3) from the star point (U) and the associated phase (t) of the converter ( 2 ) separates and the voltage induced in this winding (U _i ) of the electronic evaluation unit ( 4 ) and the inputs of the rectifier ( 5 ) and that leads in one of the connecting lines to the connections this winding with the inputs of the rectifier ( 5 ) a switching element (S5) which can be controlled by the control unit ( 3 ) is arranged, with at least two feed lines being separated from the converter ( 2 ) after detection of the triggering event and the switching element (S5) in the closed state State is controlled ( Fig. 4). 15. The apparatus of claim 9 or 10, characterized in that the electric motor ( 1 ) has an additional winding (W4), the connections of which are connected to the electronic evaluation unit ( 4 ) and the inputs of the rectifier ( 5 ) that in one of the connecting lines to the rectifier ( 5 ) a switchable by the control unit ( 3 ) switchable switching element (S5) is arranged, after detecting the triggering event at least two feed lines from the converter ( 2 ) separated and the switching element (S5) in the closed State is controlled ( Fig. 5).